DeepDispatch: Deep Reinforcement Learning-Based Vehicle Dispatch Algorithm for Advanced Air Mobility

Varnousfaderani, Elaheh Sabziyan; Shihab, Syed A. M.; Dulia, Esrat F.

doi:10.2514/1.d0416

Journal of Air Transportation

2024

DOI: 10.2514/1.d0416

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DeepDispatch: Deep Reinforcement Learning-Based Vehicle Dispatch Algorithm for Advanced Air Mobility

Elaheh Sabziyan Varnousfaderani,

Syed A. M. Shihab,

Esrat F. Dulia

Abstract: Near-future air taxi operations with electric vertical takeoff and landing aircraft will be constrained by the need for frequent recharging and limited takeoff and landing pads in vertiports and will be subject to time-varying demand and electricity prices, making the dispatch problem unique and particularly challenging to solve. Previously, the authors have developed optimization models to address this problem. Such optimization models, however, suffer from prohibitively high computational run times when the … Show more

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Cited by 3 publications

References 43 publications

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An integrated supply chain network design for advanced air mobility aircraft manufacturing using stochastic optimization

Dulia,

Shihab

2024

Supply Chain Analytics

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An integrated supply chain network design for advanced air mobility aircraft manufacturing using stochastic optimization

Dulia,

Shihab

2024

Supply Chain Analytics

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Building Public–Private Partnerships for Advanced Air Mobility Infrastructure Using Game Theory

Dulia,

Shihab

2024

Journal of Air Transportation

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To operationalize advanced air mobility (AAM) and realize its potential market value, AAM infrastructure development is needed. However, the investment required for this often exceeds the individual capacity of state governments. The challenge for state governments lies in deciding whether they can independently invest in the entire infrastructure or whether they should form public–private partnerships (PPP) with private entities. To aid state governments and policymakers in making informed decisions on AAM infrastructure investment, we have devised two models: one without PPP, identifying the optimal timing for the state governments to independently invest in AAM infrastructure in specific cities over a given analysis horizon, and the other with PPP, focusing on resolving a PPP game for AAM infrastructure investment involving state governments and private investors. The PPP model addresses uncertainties and risks in AAM operations and allows renegotiation between investors in case of unexpected situations. The equilibrium solutions generated from the PPP model reveal optimal strategies for state governments and private investors. Results highlight the required investment amounts, the optimal investment times, and the investment returns for both players. Additionally, parametric analysis is conducted by varying critical parameters to observe how these variations affect outcomes for both investors.

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Preventing aircraft from wildlife strikes using trajectory planning based on the enhanced artificial potential field approach

Cai,

Zhou

2024

MINA

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<abstract> <p>Wildlife strikes refer to collisions between animals and aircraft during flight or taxiing. While such collisions can occur at any phase of a flight, the majority occur during takeoff and landing, particularly at lower altitudes. Given that most reported collisions involve birds, our focus was primarily on bird strikes, in line with statistical data. In the aviation industry, aircraft safety takes precedence, and attention must also be paid to optimizing route distances to minimize operational costs, posing a multi-objective optimization challenge. However, wildlife strikes can occur suddenly, even when aircraft strictly adhere to their trajectories. The aircraft may then need to deviate from their planned paths to avoid these collisions, necessitating the adoption of alternative routes. In this article, we proposed a method that combines artificial potential energy (APE) and morphological smoothing to not only reduce the risk of collisions but also maintain the aircraft's trajectory as closely as possible. The concept of APE was applied to flight trajectory planning (TP), where the aircraft's surroundings were conceptualized as an abstract artificial gravitational field. This field exerts a "gravitational force" towards the destination, while bird obstacles exert a "repulsive force" on the aircraft. Through simulation studies, our proposed method helps smooth the trajectory and enhance its security.</p> </abstract>

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DeepDispatch: Deep Reinforcement Learning-Based Vehicle Dispatch Algorithm for Advanced Air Mobility

Cited by 3 publications

References 43 publications

An integrated supply chain network design for advanced air mobility aircraft manufacturing using stochastic optimization

An integrated supply chain network design for advanced air mobility aircraft manufacturing using stochastic optimization

Building Public–Private Partnerships for Advanced Air Mobility Infrastructure Using Game Theory

Preventing aircraft from wildlife strikes using trajectory planning based on the enhanced artificial potential field approach

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